Study of adenovirus-mediated dystrophin minigene transfer to skeletal muscle by combined microscopic display of adenoviral DNA and dystrophin.

In situ DNA hybridization of an E4 adenoviral sequence amplified by in situ polymerase chain reaction (PCR) was used to mark adenovirus-containing myonuclei in muscles of immunocompetent and immunosuppressed mdx mice following intramuscular injection of adenoviral recombinants. The adenoviral recombinants contained a 6.3-kb dystrophin cDNA (minigene) driven by a cytomegalovirus (CMV) promoter/enhancer and thus, immunostaining for dystrophin of the same sections permitted correlation of adenoviral recombinant-containing myonuclei with dystrophin positivity of the same muscle fiber segments. As early as 2 hr post-injection of adenoviral recombinant, an appreciable number of adenoviral recombinant-positive (AVR+) myonuclei, and some partial dystrophin positive (pdys+) fibers were observed. Some fully dystrophin-positive (dys+) muscle fibers were present as early as 6 hr. The maximum number of fibers containing AVR+ myonuclei (observed by 72 hr) was maintained until 60 days in immunosuppressed, but not in immunocompetent, animals. In immunocompetent animals, the maximum number of dys+ fibers was observed at 10 days. The vast majority of these fibers contained AVR+ myonuclei; however, by 60 days, dys+ fibers disappeared with some AVR+ myonuclei persisting. Our studies suggest that widespread delayed inactivation of the dystrophin expression cassette is probably unlikely. Thus, optimization of immunosuppression could assure successful long-term dystrophin gene transfer for gene therapy.

Impairment of force generation after adenovirus-mediated gene transfer to muscle is alleviated by adenoviral gene inactivation and host CD8+ T cell deficiency.

Recombinant adenovirus vectors (AdV) hold promise as a means of delivering therapeutic genes to muscle in diseases such as Duchenne muscular dystrophy (DMD). However, we have previously shown that the use of AdV is hampered by the development of reduced force-generating capacity, which occurs within 1 week and is progressive up to at least 1 month after AdV delivery in immune-competent animals. Determinations of muscle force production provide a sensitive and clinically important measure of potential adverse effects of AdV-mediated gene transfer on muscle cell function. In the present study, we investigated the role of AdV-related gene expression and host T lymphocyte responses in the genesis of muscle dysfunction following AdV injection of muscle. We report that UV-irradiation of AdV particles, which reduced AdV transcriptional activity without impairing infectivity (as confirmed by in situ polymerase chain reaction), significantly reversed early (4 days post-injection) AdV-induced contractile impairment in immune-competent mice as well as in mice lacking effective CD8+ T cell activity. The superimposed additional reduction in force-generating capacity normally found between 4 and 30 days post-AdV delivery in immune-competent mice, along with the associated loss of transgene (beta-galactosidase) expression, was largely abrogated by the absence of an intact CD8+ T lymphocyte response. Furthermore, short-term administration of a neutralizing antibody against CD4+ T cells significantly prolonged transgene expression and showed a trend toward mitigation of AdV-induced reductions in force-generating capacity. Cellular infiltration and humoral immune responses against the vector and transgene product were also blunted to varying degrees in the setting of CD8+ or CD4+ T cell deficiency. We conclude that AdV-related gene expression has an early negative (probably toxic) effect on muscle cell function that is independent of CD8+ T cell-mediated immunity. In contrast, further progression of contractile impairment and the accompanying loss of transgene expression from AdV-injected muscle are largely dependent upon the activity of CD8+ T cells. These results have implications for the design of future generation vectors and the potential need for immunosuppressive therapy after AdV-mediated gene transfer to muscle.

Two patients with distal muscular dystrophy and autonomic nerve dysfunction.

Two female patients with distal muscular dystrophy (Miyoshi) are reported. Neurological examination revealed marked weakness and a low skin temperature of both lower legs, especially over the gastrocnemius muscle. Biopsy specimens of the anterior tibial muscle exhibited myopathological features compatible with a dystrophic change and showed positive dystrophin reactions with all six antibodies used. Autonomic nerve studies in both patients, including laser Doppler flowmetry (LDF), component analysis of the cardiographic R-R interval and a sympathetic skin response (SSR) test, demonstrated marked abnormalities, such as sensitive vasoconstrictive responses, a suppressed peak of low frequency components and an absence of SSR, respectively, compared with findings in healthy controls. Sympathetic nerve blocking by means of epidural anesthesia produced clinical improvement and a marked decrease in the serum CK level in one patient. Although the etiology of autonomic nerve disturbances in these cases remains to be elucidated, a positive immunoreactivity of nerve growth factor receptor (NGFR) implies the possibility of some unknown sympathetic neurovascular disorder involving muscle degeneration.

Dystrophin: localization and presumed function.

To determine the localization and functional significance of dystrophin, we studied various tissues from almost the entire body of control and mdx mice, and control rats, using polyclonal antibodies against dystrophin. We observed a dystrophin reaction in synaptic regions such as neuromuscular junctions, the equatorial region of intrafusal muscle fibers, the outer plexiform layer of the retina, the myoepithelial cell layer of salivary and sweat glands, tactile nerve endings, and neurons in the brain. These dystrophin-positive regions reportedly contain actin filaments as a common characteristic, which is compatible with the dystrophin cDNA sequence. Dystrophin was absent in these regions in mdx mice. These results suggest that dystrophin plays an important physiological and/or structural role in cell motility as a trigger for propagating contractile force in, for example, the conduction system, with some relationship between actin filaments.